Citrate Synthase: Difference between revisions
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==The Structure and Mechanism of Citrate Synthase== | ==The Structure and Mechanism of Citrate Synthase== | ||
<applet load='2cts' size='300' color='white' frame='true' align='right' caption='Citrate Synthase Closed Form' name='closed'/> <applet load='1cts' size='300' color='white' frame='true' align='right' caption='Citrate Synthase Open Form' name='open'/> | <applet load='2cts' size='300' color='white' frame='true' align='right' caption='Citrate Synthase Closed Form' name='closed'/> <applet load='1cts' size='300' color='white' frame='true' align='right' caption='Citrate Synthase Open Form' name='open'/> | ||
Citrate synthase is an enzyme active in the mitochondria, where it is responsible for catalyzing the first reaction of the citric acid cycle (Krebs Cycle): the condensation of acetyl-CoA and oxaloacetate to form citrate. | Citrate synthase is an enzyme active in the mitochondria, where it is responsible for catalyzing the first reaction of the citric acid cycle (Krebs Cycle): the condensation of acetyl-CoA and oxaloacetate to form citrate. The standard free energy change (ΔG°’) for the citrate synthase reaction is -31.5kJ/mol <ref name="voet">Voet, Donald, Judith G. Voet, and Charlotte W. Pratt. Fundamentals of Biochemistry: Life at the Molecular Level. Hoboken, NJ: Wiley, 2008.</ref>. | ||
'''Structure:''' Citrate synthase is a single amino acid chain <scene name='Daniel_Eddelman_Sandbox_2/Cts_open_monomer/1'>monomer</scene>. Biologically, however, it exists as a | '''Structure:''' Citrate synthase is a single amino acid chain <scene name='Daniel_Eddelman_Sandbox_2/Cts_open_monomer/1'>monomer</scene>. Biologically, however, it exists as a | ||
<scene name='Daniel_Eddelman_Sandbox_2/Cts_open_monomer/2'>homodimer</scene>. Each identical subunit consists of a large and a small domain, and is comprised almost entirely of α helices (making it an all α protein). In its free enzyme state, citrate synthase exists in “open” form, with its two domains forming a cleft containing the substrate (oxaloacetate) binding site (PDB: [[1cts]]) <ref>PMID:7120407</ref>. When oxaloacetate binds, the smaller domain undergoes an 18° rotation, sealing the oxaloacetate binding site and resulting in the <scene name='Daniel_Eddelman_Sandbox_2/Closed_homodimer/1' target='closed' >closed conformation</scene> (PDB: [[2cts]]). This conformational change not only prevents solvent from reaching the bound substrate, but also generates the acetyl-CoA binding site. This presence of “open” and “closed” forms results in citrate synthase having Ordered Sequential kinetic behavior <ref name="voet" | <scene name='Daniel_Eddelman_Sandbox_2/Cts_open_monomer/2'>homodimer</scene>. Each identical subunit consists of a large and a small domain, and is comprised almost entirely of α helices (making it an all α protein). In its free enzyme state, citrate synthase exists in “open” form, with its two domains forming a cleft containing the substrate (oxaloacetate) binding site (PDB: [[1cts]]) <ref>PMID:7120407</ref>. When oxaloacetate binds, the smaller domain undergoes an 18° rotation, sealing the oxaloacetate binding site and resulting in the <scene name='Daniel_Eddelman_Sandbox_2/Closed_homodimer/1' target='closed' >closed conformation</scene> (PDB: [[2cts]]). This conformational change not only prevents solvent from reaching the bound substrate, but also generates the acetyl-CoA binding site. This presence of “open” and “closed” forms results in citrate synthase having Ordered Sequential kinetic behavior <ref name="voet" />. | ||
'''Mechanism:''' The reaction mechanism for citrate synthase was proposed by James Remington. In this mechanism, three ionizable side chains in the | '''Mechanism:''' The reaction mechanism for citrate synthase was proposed by James Remington. In this mechanism, three ionizable side chains in the | ||